Post on 02-Mar-2022
Diversity 2015, 7, 270-294; doi:10.3390/d7030270
diversity ISSN 1424-2818
www.mdpi.com/journal/diversity
Article
Drastic Population Size Change in Two Populations of the Golden-Striped Salamander over a Forty-Year Period—Are Eucalypt Plantations to Blame?
Jan W. Arntzen
Naturalis Biodiversity Center, P. O. Box 9517, 2300 RA Leiden, The Netherlands;
E-Mail: pim.arntzen@naturalis.nl; Tel.: +31-71-5271921; Fax: +31-71-5687666
Academic Editor: Mario A. Pagnotta
Received: 3 April 2015 / Accepted: 21 July 2015 / Published: 30 July 2015
Abstract: Over the last half century the Iberian peninsula has seen the large scale planting
of exotic gum trees (Eucalyptus sp.) therewith reducing space for native wildlife. An
additional effect of the gum tree plantations may be the lowering of the water table in
adjacent streams, to which amphibian species with a larval niche in the running sections of
small streams would be especially susceptible. In northwestern Iberia that niche is occupied
by the Golden-striped salamander, Chioglossa lusitanica. I here report on the demographic
trends of two C. lusitanica populations over a forty-year period, in two areas of one mountain
range near Porto in northwestern Portugal. In both areas advantage was taken of the
migration pattern of C. lusitanica to sites for aestivation and breeding in summer and fall.
The area of the Silveirinhos brook was transformed in a plantation of gum trees shortly after
the research started, while the area of Poço do Inferno remained virtually unaffected. At
Silveirinhos the adult C. lusitanica population declined by one or two orders of magnitude,
from ca. 1500 individuals to less than 50 at present. Demographic models that operate under
a uniform larval mortality yielded population sizes that are compatible with field
observations, including the late onset of the decline at 14 or more years after the planting of
the gum trees and the near-extinction at year 32. An alternative reason for the relatively
recent population collapse of C. lusitanica may have been disease, but no sick individuals or
corpses have become available for clinical investigation. Conversely, the control population
at Poço do Inferno increased in size by a factor of five or more. These data support the
hypothesis that gum tree plantations have a strong negative effect on C. lusitanica. The
population size increase at Poço do Inferno is probably attributable to the installation of
wastewater treatment in the adjacent town of Valongo, with a discharge in the Simão river
and closely connected to Poço do Inferno. This result suggests that the Simão river
OPEN ACCESS
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contributes to the Poço do Inferno population and that medium-large streams may constitute
prime C. lusitanica habitat. Larval mortalities estimated for stable and declining populations
are remarkable close (0.69 and 0.73, respectively), but dissimilar to the larval mortality at
ca. 0.51 of an increasing population such as at Poço do Inferno. Suggestions for further
research include (i) the continued monitoring of the Silveirinhos population with inspections
at 5–10 year intervals, and (ii) checking for the persistence of C. lusitanica populations in
and around gum tree plantations where the species was reported decades ago.
Keywords: amphibian decline; Chioglossa lusitanica; demographic modelling; gum tree;
Iberia; monoculture; Portugal; Urodela; Vortex
1. Introduction
To document and understand natural population size fluctuations in long-lived animal species such
as many vertebrates requires long-term data. To distinguish natural fluctuations from a pattern of change,
such as may be expected from large-scale anthropogenic activities, requires even more data. Long-term
data are, however, notoriously difficult to obtain. One dramatic change in the landscapes of southwestern
Europe has been the planting of exotic gum trees (Eucalyptus sp.) over vast areas and one of the most
drastic projects took effect in the last quarter of the 20th century, through the Portuguese Forestry Project
with assistance of the World Bank [1,2]. In Portugal, the area with gum tree plantations—mostly the
Tasmanian blue gum, Eucalyptus globulus—has increased eight-fold from the mid 1960s to a coverage
of ca. 25% of today’s forested area, with a substantial reduction in space for native wildlife as a
consequence. An additional effect may be a reduced run-off causing watercourses to dry up early in the
season, even if the streambed itself was not affected by the plantation. Such a drying effect would be
most detrimental to species that live in the running section of streams [3,4]. I set out to study the possible
effect of the large scale planting of gum trees in an area in the vicinity of Porto, Portugal, where shortly
before I had studied the natural history of an enigmatic amphibian, the Golden-striped salamander,
Chioglossa lusitanica (Figure 1). The study took place along two headwater streams at different slopes
of one mountain range. One area remained unaffected, whereas in 1980 the other area was turned into a
gum tree plantation. The planting involved the rip-plowing of the Serra de Santa Justa, except for a ca.
20 m wide buffer zone covering the Ribeira de Silveirinhos and its margins, as required by Portuguese
law [5]. With data going back to 1976, the control population has increased in size, whereas the
population at the gum tree plantation has decimated.
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(A)
(B)
(C)
Figure 1. Golden-striped salamander, Chioglossa lusitanica: (A) adult, drawing and copyright
Bas Blankevoort © Naturalis Biodiversity Center, reproduced from [6] with permission;
(B) embryos in various stages of development, Photo M. Sparreboom; and (C) first-year
larva, Photo JWA.
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2. Materials and Methods
2.1. Study Areas and Fieldwork
The two study areas, called “Ribeira de Silveirinhos” and “Poço do Inferno”, are located at the
northern flanks of the Serra de Santa Justa, immediately south of the town Valongo at ca. 10 km east of
Porto, Portugal. The Silveirinhos brook runs in southerly direction, has a length of 4 km and discharges
in the Rio Ferreira. The Poço do Inferno brook runs in northeastern direction, has a length of ca. 600 m
and discharges in the Simão river. The distance between the study plots is 1340 m “as the crow flies”,
while the “as the salmon swims” distance along the Ferreira and Simão rivers is ca. 10 km (Appendix 1
with Figure A1).
The Ribeira de Silveirinhos is a small semi-permanent mountain brook in slate and quartzite terrain.
In a zone of up to 30 m wide the valley has a dense vegetation of Alnus glutinosa, Eucalyptus globulus
and Acacia sp., with an undergrowth of brambles, Digitalis purpurea, Pteridium aquilinum and gum tree
and Acacia shoots. The search plot is situated close to the Silveirinhos source and includes a dry stone,
V-shaped built structure of ca. 720 m3—presumably constructed from the debris of a local excavation—
spanning the valley (41.17330°N, 8.50080°W). This “dam” of 28 m length, up to 7 m high and up to 22
m wide has a tunnel for the stream to run through (see Figure 1 in [7]). The age of the dam is unknown,
but judging from the size of the trees growing on top of it, already in 1977, it must have been old. The
tunnel, the dam wall, the brook and the vegetated zones at either side over the 200 m long downstream
section of the brook were regularly surveyed by night for post-metamorphic C. lusitanica. The open
maquis vegetation at further distance from the brook was initially inspected also, but no golden-striped
salamanders (Chioglossa) were found and searching outside of the densely vegetated zone was
abandoned. By daylight the selected stretch of the Silveirinhos was dip-netted for larvae of C. lusitanica
and other amphibian species. In the 1979–1981 period the Serra de Santa Justa and adjacent mountain
ranges were rip-plowed and transformed from semi-natural open maquis (see Figure 4 in [8]) into gum
tree plantations almost entirely (details for the Valongo municipality are in Figure 8 in [9]), but the
planting on newly created terraces stopped short of the densely vegetated zone at ca. 10 m from the
Silveirinhos brook. The area upstream of the dam remained unchanged. The area is rather left alone and
I have observed no management of the gum tree plantations other than the clear-cutting of sections.
The “Poço do Inferno” is a small impermanent mountain brook in schistose/quartzite terrain rich in
iron oxide and with a vegetation consisting of Pteridium aquilinum, Cytisus striatus, Calluna vulgaris,
Erica sp. and Frangula azorica and stands of gum and pine trees on its banks (see Figure 3 in [7]).
Several narrow and more or less deep corridors with entrances close to the brook were built for
gold-digging in Roman times (locally called “minas” [10]). However, bore holes from modern
machinery witness a more recent human activity. The research was carried out in two mines, the “Upper
mine” with the entrance at 41.18064°N and 8.48816°W at a distance of 260 m from the Simão, and the
“Lower mine” with the entrance at 41.18185°N and 8.48677°W at 80 m from the Simão. The
investigated area includes an 80 m section of the brook in between them, upstream from the dirt road
crossing the brook.
Both mines consist of a main gallery and two side galleries, roughly laid out in the shape of a cross
(Appendix 2 with Figure A2). Galleries are up to 2 m wide. The height allows straight up walking except
Diversity 2015, 7 274
at several places deeper in the mines that are littered with heaps of rock debris. The Upper mine has
shallow but permanent standing water for the deeper part of the main gallery and a water level of ca. 25
cm in one short side gallery. This mine has an additional gallery starting near the entrance. This stretch
of ca. 25 m length is fairly dry, rarely visited by C. lusitanica and, with a few exceptions, was not
included in the searches. The entrance of the Upper mine is located at a short distance from the Poço do
Inferno brook with no observable discharge, except after periods of very heavy rain when the mine’s
water level rises markedly as to overflow the heap of soil at the entrance (see Figure 4 in [7]). In the
Lower mine water drips down the walls and the ceilings at many points and a small stream runs through
the mine permanently and at the mine entrance discharges in the Poço do Inferno brook. The main gallery
is wetter than the two arms at either side. Both mines were prospected over their length of ca. 105 m
(Upper mine) and 236 m (Lower mine). Adult salamanders and mated pairs were counted along with a
rough count of the number of eggs (or, actually, embryos) (Figure 1). A further search by turning stones
from the heaps of stone debris indicated the presence of many more adult and embryonic C. lusitanica,
but this was not carried through, because of the danger of harming salamanders and the work
load involved.
I explored for the presence of an underground connection from the Upper mine to the Poço do Inferno
brook. In spring 2011 an aqueous solution containing 60 g Fluorescein sodium salt (Sigma F6377) was
released in the standing water section deep in the Upper mine. Water samples of 50 ml were taken at the
Poço do Inferno brook at 20 m upstream (negative control), aside and at 170 m downstream of the
entrance of the Upper mine, at eight-hour intervals over a three day period. The pooled samples were
measured for Fluorescein with a Perkin Elmer LS 45 Fluorescence Spectrometer under FL WinLab
software and a detection limit of 0.013 µg Fluorescein/L.
2.2. Pattern of Annual Migration
The dam serves as an aestivation site for adult Chioglossa salamanders that in fall, winter and spring
reside along the brook [8,11]. Both mines are places of C. lusitanica shelter, mating and egg-deposition.
In both areas, observations on C. lusitanica were made on a regular basis in the spring, summer and
autumn of 1977 and irregularly ever since. Most visits were during the autumnal period of reproduction.
Egg numbers for 1976 were estimated in early spring 1977, by a count of molded embryos and the empty
gelatinous shells left behind by hatched embryos. In the course of 1977 and in October 2010, adult
salamanders in the dam were marked by toe-clipping. The adult population size was calculated with
Begon’s weighted mean method [12], based upon the recapture of marked salamanders. Additional data
have become available from colleagues and from the literature.
2.3. Natural History of Chioglossa lusitanica and Unknowns
The Golden-striped salamander is an exceptionally slender and long-tailed salamander of the family
Salamandridae, endemic to the northwestern corner of the Iberian Peninsula. While described 150 years
ago [13], C. lusitanica remained virtually unstudied until a broad survey in 1957 [14] and my own ecological
work in the late 1970s [15,16]. More has become known about the ecology of the species [4,17,18] and
about important life history parameters such as demography and reproductive cycle [19,20]. The species
distribution is by now well documented [21–23] and we have some knowledge on morphological
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variation [24–26] and phylogeography [27–30]. By far the most prominent feature of C. lusitanica is its
dependency on conditions of moisture, which is reflected by (i) a distribution confined to areas of high
precipitation (>1000 mm annually); (ii) a drought-induced pattern of migration along the brooks, for
which distances of >350 m overnight have been recorded; and (iii) a period of aestivation followed by
mating and egg-laying in the rainy season [16]. Still, many questions regarding the life history of
C. lusitanica are open, especially on the early stages of life, the use of underground habitats and dispersal.
2.4. Population Modeling
The population demography of C. lusitanica was modeled with Vortex 10 [31]. The variables required
for modeling fell into one of four categories: (i) inferred from general amphibian knowledge
(e.g., breeding system); (ii) known or inferred from the literature, including present paper (adult age
distribution, sex-ratio, clutch size, adult mortality, population size at the start of the experiment, etc.);
(iii) virtually unknown and modeled over a wide range of possible conditions (carrying capacity, K); and
(iv) the parameter of interest as hypothesized to be affected by the planting of gum trees (larval mortality,
ql). Scenarios in which larval mortality was not uniform over time (e.g., “continuous change” or “broken
stick” models) were not carried out because of the lack of data over the 1996–2009 period. The life table
produced by Vortex indicates that the size of the breeding population is typically 1/5th–1/6th of the total
population. Vortex was run for 1000 iterations per set of variable combinations. For details on how the
demographic parameters were determined see Appendix 3 along with Figure A3. In the below Ň refers
to population size estimates, Ń refers to census population size and Ñ refers to modeled population size
and ql and qb are larval and breeding adult annual mortality rates, respectively.
3. Results
With data from the literature and colleagues included, estimates on the C. lusitanica adult population
size (Ňb) in the dam were made on seven annual occasions (Appendix 4). Larval counts (Ńl) for the
Silveirinhos brook were made on five annual occasions. Counts on the numbers of adults (Ńb) and
embryos (Ńe) in the Poço do Inferno mine galleries were made on 12–16 annual occasions. The size of
the adult C. lusitanica population in the Silveirinhos dam was estimated at Ňb = 1324 with a standard
error (SE) of 265 in 1977, at Ňb = 1477 ± 207 in 1992 and at Ňb = 113 ± 56 in 2010. In 1977, the number
of larvae dip-netted in the adjacent 200 m long section of the Siveirinha brook was maximally 81
first-year larvae and eight second-year larvae. In 2015, these numbers were five and three, respectively.
The maximum number of adults observed in the Upper mine was Ńb = 78 in 1977 and 279 in 2014. In
the Lower mine the numbers were 100 in 1977 and 336 in 2014. The embryos numbers counted in the
mines rose gradually from Ńe ~650 in 1976 to ca. 3550 in 2014. The most telling data points are probably
those of 1977 and 1995 when accumulate counts of freshly deposited eggs were made over 16-25 visits
spanning the entire reproductive period. These counts gave Ńe ~ 550 in 1977 and ca. 5000 in 1995. In
1977, the ratio of juveniles to adults was Ńj/Ńb = 0.42 along the Silveirinhos brook (751 salamanders in
17 visits) and 0.55 along the Poço do Inferno brook (116 salamanders in 11 visits). No juveniles were
observed inside the dam or in the mines. Over the 39 years of study, the pattern is that of a sharp
population decline at the Silveirinhos and a substantial increase at the Poço do Inferno (Figure 2).
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Figure 2. Numbers of Chioglossa lusitanica observed and population sizes estimated
in the Serra de Santa Justa in northwestern Portugal over the 1976–2015 period.
(Top panel) Embryo (round symbols) and adult numbers (squares) counted in two mine
galleries at Poco do Inferno. The 1977 and 1995 cumulative embryo counts are shown
separately with solid round symbols. (Bottom panel) First-year larvae counted in the Ribeira
de Silveirinhos (crosses) and adult population size estimates from capture–mark–recapture
in the “dam” (squares, Ňb solid symbols, Ňb ± SE open symbols). For numerical detail see
Appendix 4.
Following the application of Fluorescein in the Upper mine the concentrations in the Poço do Inferno
brook were 0.26 µg Fluorescein/L adjacent to the mine entrance and 1.49 µg Fluorescein/L at 170 m
downstream. The control sample (upstream of the Upper mine) was under the detection limit.
I let Vortex determine the values of ql at which a hypothetical Chioglossa population would
retain a 10,000 initial population size at year 100 with demographic parameter values as in Appendix 3.
A stable population (rate of increase rstoch = 0 [31]) is obtained at ql = 0.69 when qb = 0.22 and
at ql = 0.62 when qb = 0.28 (Figure 3). A ten-fold population size increase, such as observed at
Poço do Inferno, is associated with ql = 0.51 when qb = 0.22 and with ql = 0.38 when qb = 0.28.
Demographic modeling further indicated that the recent low population size at Silveirinhos may be
associated with a uniform larval mortality since the planting of gum trees in 1980 of ql = 0.76–0.79
(2010, 30 years) (Figure 4). The figure also shows that K has little effect on such a declining population,
in particular if ql > 0.70.
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Figure 3. Population size development in a hypothetical population of Chioglossa lusitanica
as a function of adult mortality (qb, vertical axis) and larval mortality (ql, horizontal axis)
modeled with Vortex. The curved line indicates parameter combinations at which population
size is stable (rstoch = r = 0 [31]). Higher and lower q-values result in declining and increasing
population sizes, respectively. The situation in which adult mortality is higher than larval
mortality (parameter space shaded, qb > ql) is considered unrealistic. For details see text and
Appendix 3. Round symbols refer to parameter combinations determined for Poço do Inferno
where population size is increasing and square symbols refer to parameter combinations
determined for the declining Ribeira de Silveirinhos population (symbols as in Figure 2).
Figure 4. Adult population size of Chioglossa lusitanica at the Ribeira de Silveirinhos
modeled with Vortex (log Ñb median value, vertical axis) as a function of larval mortality
(ql, horizontal axis) modeled with Vortex under a carrying capacity of K = 33,000. The year
is 2010, i.e., at 30 years after the widespread planting of gum trees. The dots drawn in for
low ql values represent the modeled variation in carrying capacity of, from top to bottom,
100,000, 70,000, 50,000, 20,000, 10,000 and 7000. Note that the size of the breeding
population is about 1/5th–1/6th of the total population; for details see Figure A3 in Appendix 3.
The horizontal lines represent the adult population size as estimated in 2010 (logŇb ± SE)
and the interrupted vertical lines indicate the values of larval mortality at which modeled and
observed data coincide, at around ql = 0.78 (0.77 < ql < 0.80).
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More precise figures are derived from plotting the proportion of modeled population sizes (Ñb) as
falling inside or outside the Ňb ± SE range, with ql varying over the 0.5–1.0 range (Figure 5). The 1984
(4 year) and 1994 (14 years) population size estimates do not help to secure ql estimates, presumably
because the population had little opportunity to already decline (1984 [3]) or because the precision was
poor (1994 [32]). The fairly precise 1992 estimate (12 years) is incompatible with ql < 0.58 and
ql > 0.83 and the estimate of near-extinction in 2012 (32 years) is incompatible with ql < 0.70. By its
own the 2010 (30 years) Ňb estimate is the most informative with a range of 0.70 < ql < 0.86 and a best
estimate of ql = 0.78. Considering all data points, the best estimate for ql is in the 0.70–0.83 range
(Figure 5). Under a higher adult mortality (from qb = 0.22 to qb = 0.28) the ql estimates decrease by
ca. 8% points (e.g., from 0.73 to 0.65; Appendix 5 along with Figure A4). New and additional
information on this project may be placed at http://www.repository.naturalis.nl/record/569285 under the
sole responsibility of the author.
Figure 5. The probability of modeled population sizes of Chioglossa lusitanica at Ribeira
de Silveirinhos falling within the population size range estimated in the field (Ň ± SE), as a
function of larval mortality (ql, horizontal axis). Populations were modeled with Vortex
for 4–32 years following the widespread planting of gum trees in 1980. The results were
fitted to a Gaussian distribution with Prism 6 software [33] (r2 > 0.95) and then log-transformed.
Support is maximal for ql = 0.73 (purple bar, p > 0.10). The grey rectangle indicates the
0.70 < ql < 0.83 range over which none of the Ñ - Ň combinations are implausible (p > 0.05).
The green bar highlights the ql = 0.78 value already retrieved for 2010 in Figure 4. Adult
mortality qb is set at 0.22; for results with qb = 0.28 see Appendix 5.
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4. Discussion
4.1. Population Development at Ribeira de Silveirinhos
The adult population size of C. lusitanica in the Silveirinhos dam was in the order of Ň = 1300–2200
in the 1977–1994 period and ca. 100 in 2010 (Figure 2). Observations at 11 monthly visits in 2012–2013
yielded ten sightings and just two salamanders were caught, so that a capture–mark–recapture estimate
was impossible to make [34]. The data indicate a decline in C. lusitanica adult population size of one or
two orders of magnitude. However, some assumptions are implicit to this conclusion and for interpreting
the data it is important to understand the spatial dynamics of C. lusitanica at the Silveirinhos brook and
dam system.
The schist and quartzite structure of the Serra de Santa Justa does not provide deep shelter and the
thin layer of soil dries out quickly. The Silveirinhos dam serves as a summer hiding site for the adult
population that at wetter periods of the year is distributed along the brook. The decision to migrate to
the dam or stay put depends on the quality and depth of the shelter the individual salamander is in [11].
The total length of the Silveirinhos over which Chioglossa salamanders migrate to the dam is not known,
but distances of >700 m have been recorded [7]. In summer 1994, the population size of the dam was
estimated at Ňb = 1974 and the density of adult C. lusitanica in winter 1994–1995 was estimated at
11.4 ± 2.16 per m of brook [32]. Arntzen concluded that 60% of adult salamanders in the 200 m stretch
downstream of the dam used the dam for aestivation, so that a length of ca. 330 m of the brook would
account for the numbers estimated for the dam [8].
Is the decline real? One explanation for the low numbers of adult C. lusitanica in the dam in recent
years is that migration for aestivation is no longer required, for example because the newly created gum
tree terraces provide deep and sufficiently moist shelters year round. Another possibility is that low
numbers were observed in exceptionally wet years in which migration for shelter from drought was not
required. However, these explanations do not hold since the low number of adults in the dam is paralleled
by low numbers of larvae in the brook (Figure 2, Appendix 4). In addition, adults were rare along the
brook in winter 2014 and in spring 2015. I conclude that the current C. lusitanica population size at
Silveirinhos is one or two orders of magnitude down relative to the 1977–1994 period. At this low
size, the population may be especially prone to stochastic events, eventually leading to local
extinction [31,35]. Is the population collapse at Silveirinhos to be attributed to (i) the gum tree
plantations created in 1980? Other, not mutually exclusive, explanations are (ii) destruction of the sites
that C. lusitanica uses for egg-deposition; (iii) increased competition or predation; and (iv) an outbreak
of disease.
4.2. Potential Reasons for the Decline
Gum tree plantations: The streambed of the Silveirinhos, along with a vegetated zone on either side
of the brook, stayed outside the plantation and were not structurally altered. The salamander decline is
thought to operate through a reduced aquatic run-off causing the stream to fall dry earlier in the season
and over a larger section of the valley. In rip-plowed plantations, gum tree transpiration rates remain
high even when water supply from the soil would be dwindling [36]. This would in first instance affect
the running sections of the brook, which is the larval niche of C. lusitanica [8,37]. Drought would
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therewith affect C. lusitanica more than the other local amphibians. Considering a generation time of
ca. 6 years ([19], Appendix 3), a gradual decline in C. lusitanica population size would be expected from
1980 onwards. While the precision of the dam population size estimates is low, especially for the crucial
year 1994 (Figure 2), the larval count for that year confirms that the population size of C. lusitanica was
yet substantial. A sharp decline in population size appears to have taken place only after 1994, which is
14 or more years after the creation of the gum tree plantation. For the population demographic modeling
exercise to shed light on this issue, see below.
Destruction of egg-deposition sites: At the Ribeira de Silveirinhos, the places where C. lusitanica lays
the eggs are unknown. At Poço do Inferno, oviposition takes place in the deeper parts of the mines—and
even there, frequently hidden from sight. This suggests that normally the deepest available underground
sections of the stream will be used or, at Silveirinhos, perhaps at wet and moist sites deep inside the dam.
The gum trees taproots do normally not exceed a length of 3 m [38] but roots grow quickly towards
aquatic resources and may then be reaching a depth of 14 m [39]. Gum trees are reported to exploit
aquifers through which more water is consumed than is available from precipitation [40] and could
therewith destruct Chioglossa egg-laying sites. I have, however, no information that would suggest the
physical destruction or drying up of underground habitats to explain the Silveirinhos population collapse.
Increased competition or predation: Along with the gum tree plantation, the Silveirinhos has seen the
building of a small causeway spanning the brook at the latitude of São Pedro da Cova, for use by trucks
and other forestry equipment (41.15717°N, 8.49575°W, point C in Appendix 1). With this causeway, a
pond was unintentionally created of size 17 m × 35 m. The exact date is not known, but pond creation
was after 1995 (V. Lima, pers. comm.) and when I found it in spring 2011, the aquatic vegetation was
well-developed, indicating an age of several years. Amphibian species, such as the urodeles Lissotriton
boscai, Salamandra salamandra, Triturus marmoratus, and the toad Alytes obstetricans, that have larval
stages in pond sections of the stream, are more common at Silveirinhos at the present than they were
before [41]. This raises the question, has interspecific competition among larvae increased? However,
the niche of C. lusitanica larvae is composed of the running and turbulent sections of a brook and only
overlaps with the niche of S. salamandra larvae and not with the other species [8,37]. Adult toads
(Bufo spinosus) and salamanders (Salamandra salamandra) are mentioned as potential predators [4] but
their niches are largely outside the brook margins where C. lusitanica lives and, at Santa Justa, their
density is not so high that they could extirpate the C. lusitanica population.
Outbreak of disease: In favor of this explanation is the sudden and massive decline of the C. lusitanica
population after 1994, suggesting low versus high mortality rates before and after that date. In 1994, I
observed a new arrival (the Green frog Pelophylax perezi) at the Silveirinhos and, in 2011, a small,
unidentified species of carp. These vertebrates may have served as a disease vector. Drastic patterns of
decline have been reported for a suite of amphibian species in central and northern Spain that were linked
to infections with a Chytrid fungus and a Ranavirus, respectively [42–44]. The drastic decline of the
marbled newts (Triturus marmoratus) in a pond in northern Portugal may have been caused by an
Iridovirus carried by introduced Pumpkinseed sunfish (Lepomis gubbosis) [45,46]. Unfortunately, at
Silveirinhos no surveys were carried out during the episode of population collapse and no corpses have
become available for clinical investigation. However, given that the observed population development
of the Golden-striped salamander (Figure 2) is not significantly at odds with demographic models that
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operate under a uniform larval mortality rate there is, strictly speaking, no need to invoke an ad hoc
explanation, such as disease (for a comparison, see, e.g. [47]).
4.3. Population Development at Poço do Inferno
At Poço do Inferno the data for the Upper mine and the Lower mine can be taken together because
C. lusitanica migration from one mine to the other is frequent and may occur overnight ([7,48]. At just
under one order of magnitude the local increase in C. lusitanica population size is unequivocal and can
only to a minor degree be explained by, e.g., inter-observer variation, phenology, or weather conditions.
To appreciate the healthy status of this population, it is important to note that the counts refer to visible
eggs and visible adults—many more could have been found in the heaps of rock at the deeper sections
of the mine galleries that though were left undisturbed. An increase in population size such as observed
in the Poço do Inferno population is difficult to associate with a particular value of larval mortality,
because of the dependency of ql on carrying capacity (in expanding populations) and the availability of
only count data.
Reproduction in the Lower mine can proceed unhampered. Matings are readily observed and embryos
easy to find. Hatched larvae discharge in the stream running through the mine that will eventually assist
transport to the outside. Downstream migration along the Ribeiro do Inferno over 80 m would bring the
larvae in the Rio Simão. Upstream larval migration seems improbable due to a ca. 4 m high incline
adjacent to the Lower mine entrance. The Upper mine also serves for mating and egg-deposition, over
the season the larvae getting thinner and less numerous. In March 1977 and October 2010, I observed
second-year larvae that may have been feeding on unfertilized eggs, dead embryos or larvae, since no
other food sources than C. lusitanica itself appear to be available [49]. The water in this mine is stagnant
with no visible connection to the outside, with the exception of periods of excessive rain. The water to
overflow the heap of soil at the entrance of the mine has been observed on two occasions (March
1977 [50] and November 1994 [51]). The Fluorescein measured in the lower section of the Poço do
Inferno brook indicates the presence of an underground aquatic connection with the Upper mine, but if
the openings are large enough for Chioglossa larvae to pass it is not known. All in all, it is difficult to
determine to what extent Chioglossa reproduction in the Upper mine contributes to the Ribeiro do
Inferno population, but the mine’s continued use for reproduction—quite possibly for 2000 years—
suggests that it is unlikely to be negligible. Still, a simple and effective conservation measure would be
the removal of the heap of soil at the mine entrance, so that larvae staying behind will be washed out of
the mine following periods of rainfall.
At the Poço do Inferno, obvious environmental change has been absent. This edge of the Serra de
Santa Justa remained free of large-scale gum tree plantation and the mines and their immediate surroundings
are essentially unchanged. Minor changes in the area involve the remodeling of some of the dirt tracks,
the local extraction of wood and the creation of fire break zones. Most pine trees fell victim to forest fires
and were taken over by gum trees, but the area stayed free of terraced plantations such as at the Ribeira
de Silveirinhos (see Figure 23 in [9]). One prominent change just outside the research area is the cleaning
of the Simão stream through the installment of facilities for sewage treatment in Valongo in the early
1980s. Prior to this, the Simão was an opaque and smelling stream with plentiful remains of cloth
washing and other household rubbish. The Simão valley saw further environmental improvement
Diversity 2015, 7 282
through the project “Requalificação Paisagística das Margens do Rio Simão” and at present, the stream
makes a clean and biologically healthy impression (http://www.valongoambiental.com). In the absence of
other environmental change I attribute the drastic population size increase of C. lusitanica at Poço do
Inferno to the improved health of the Simão River. The section of the Simão adjacent to the Poço do
Inferno (in between Valongo and Campo) may be particularly amenable to C. lusitanica due to the lining
of the river borders with dry stone walls and even the slate roofing over a ca. 190 m long section of the
stream, presumably constructed with the stone debris from the Lower mine (Appendix 1).
4.4. Are Eucalypt Plantations to Blame? Suggestions for Future Investigations
Serious environmental problems have been attributed to gum tree plantations, foremost through a
substantial reduction of total water yields when the trees are planted in semi-arid water catchment
areas [52,53]. Toxins are released through evaporation, transferred to the soil by fog drip and leached
out from leaf litter by rain [54]. More controversial is the impact the plantations would have on soil
nutrients and erosion [1]. Gum tree plantations are typically associated with low biodiversity, including
bird wildlife [55,56] and have a negative effect on ground arthropods and on the many species of
vertebrates that depend on them as prey [57]. Others concluded that gum tree plantations have less
diverse flora and fauna than indigenous forests [52]. In central Portugal it was reported that streams
running through gum tree plantations had lower number and diversity of aquatic invertebrates than
streams running through deciduous forests, but the effect is not consistent [58,59]. The effect of frequent
logging through clear cutting may drastically affect the aquatic invertebrate and fish communities in
adjacent riverine habitats ([59] and references therein). However, the supposed negative effects of gum
trees on wildlife are frequently inconsistent or unrepeatable and alternative explanations usually cannot
be ruled out. Moreover, effects may be different for different species [60]. As for C. lusitanica, negative
effects of gum tree plantations are assumed to be indirect because the postmetamorphic salamanders live
mostly in the buffer zone between the rip-plowed stands and the stream courses. The larval niche is
likely to have become reduced, but regretfully no data on change in flow rates of the Silveirinhos
are available.
The surveying of two Chioglossa populations over four decades has yielded some remarkable results.
At the downside is a decline near to extinction of the Silveirinhos population that may be attributed to
the monoculture of gum trees since 1980. The decline is late and sharp, but demographic models indicate
that a pattern like this might be expected in ca. 12% of replicates. Nonetheless, the pattern of decline is
so strong and abrupt as to be at odds with observations that C. lusitanica is regularly present in gum tree
affected areas elsewhere [4]. Another example of an amphibian population possibly affected by an
introduced plant species is Fowler’s toad [61].
An outcome of the survey at the upside is the drastic and consistent population size increase of
C. lusitanica at the Poço do Inferno. This may be attributed to the improved health of the adjacent Simão
River. Moreover, this would suggest that C. lusitanica lives around larger streams than currently
appreciated—for a description of stream size and types with and without the species see [4]. This
hypothesis can be tested by the marking of adult salamanders along the Simão and their later retrieval in
the mines. Chioglossa lusitanica living around large streams would also explain the observation of dense
populations without local recruitment, such as at the tiny Salto brook adjacent to the Sousa River with
Diversity 2015, 7 283
ca. 6 adults per m of the brook [14,15]. The main habitat of C. lusitanica in this area could be the adjacent
Salto River. I advocate research to be undertaken to test for the regular presence and reproduction of
C. lusitanica in high-order riverine habitats. However, large rivers of the size of the Douro are probably
not a good habitat, as suggested by the barrier function of that river revealed by a substantial level of
genetic differentiation across the river [28].
In search of a definitive answer on the effects of gum tree plantations on C. lusitanica, I advocate the
resurveying of localities with and without newly created plantations that were prospected before, such
as under the “EU-life” project in northern Portugal [62] and in Galicia [4]. I also recommend that the
population size in the dam of the Silveirinhos be estimated at intervals of five to ten years. A population
size with reasonable precision may be obtained with ca. one week of work, if carried out during and
following rainy summer and autumn nights. The C. lusitanica population may rebound, either from the
small number of local survivors, or from new arrivals that would colonize the area along the lower
stretches of the Silveirinhos brook. A recovery to the level of the late past century would indicate the
absence of strong effects from the gum tree plantations on C. lusitanica. Where C. lusitanica lays its
eggs if there are no mines remains unclear. I suggest that the regular places are deep underground
sections of smaller and larger streams. However, testing this proposition will probably have to wait for
technical innovations to take place.
Acknowledgments
I thank Jason Belcher, Carl Cornish, A. Ferreira, Tom Gerats, the late Dick Hillenius,
Inigo Martínez-Solano, the late A. Mateus, Mike Richardson, Max Sparreboom, Janine Ziermann and
Annie Zuiderwijk for assistance in the field, Raluca Bancila and A. Tudorache (Institute of Speleology
‘Emil Racovitza’ of the Romanian Academy) for advice on methods in speleology and the measuring of
Fluorescein levels, Manuel M. Faria for the release of unpublished data, Inigo Martínez-Solano and
Eddy van der Meijden for constructive comments on an earlier version of the manuscript and
C. Castro Poças (Câmara Municipal of Valongo) and Fernando Sequeira for information on the local
history of mining activities and the environmental restoration program of the Simão River.
Conflicts of Interest
The author declares no conflict of interest.
Diversity 2015, 7 284
Appendix 1
Figure A1. Map of the Valongo–São Pedro da Cova area with the Serra de Santa Justa [63]. The
blue squares have a size of one km2. Points of interest are: A: dam; B: research section of
the Ribeira de Silveirinhos; C: newly created pond in the Silveirinhos streambed; D: entrance
of Upper mine at Poço do Inferno; E: entrance of Lower mine; F: Simão mine (no data
presented, inaccessible for man since 2010); and G: covered stretch of the Simão river. Note
that the two study areas are in clockwise direction interconnected downstream through the
Poço do Inferno-Simão-Ferreira river and upstream through the Silveirinhos.
Diversity 2015, 7 285
Appendix 2
Figure A2. Layout of the Upper and Lower mine. Stretches are 5 m long. Entrances at the
Poço do inferno brook are shown by “X” marks. For localities see Appendix 1.
Appendix 3. Parameter Settings for the Population Demographic Modelling with Vortex [31].
A3.1. Hypothetical Population of Chioglossa lusitanica
A3.1.1. Scenario Settings
Number of iterations: 1000 in population based analyses
Number of years: 100
Extinction definition: N < 50. This reflects the observed number of adults in the dam at the Ribeira de
Silveirinhos (Ńb = 10) at the most recent survey [34].
Number of populations: single
State variables: as defined under sensitivity testing, see larval mortality rates below.
Species description
Inbreeding depression: no
Concordance of the effect of environmental variation on reproduction and survival: no
A3.1.2. Reproductive System
Polygynous
Age of first offspring: males 5 and females 6. This ignores a few males breeding at age 4 and a few
females breeding at ages 4 and 5 (Figure 2 in [19], note that this figure shows post-metamorphic age).
Breeding at age 5 age is also suggested by the pattern of ‘lines of arrested growth’ that, as in tree rings,
Diversity 2015, 7 286
represent age and that show a tightening (“rapprochement”) at age 5, indicating the switch in resource
allocation from growth to reproduction (see also [64]).
With data for the sexes combined, the age distribution observed at the Ribeira de Silveirinhos
indicates an annual mortality qb = 0.22 (see [65]). However, the male age 5 class is relatively small and
may be underrepresented, either through chance or because it is about to join the breeding population.
Annual mortality determined from just the female age distribution gives qb = 0.28, which parameter
value was also analyzed (Appendix 5).
Maximum age of male and female reproduction: 10
Maximum lifespan: 10
Maximum number of progeny per brood (clutch size): 35
Sex ratio at birth: 50/50
Density dependent reproduction: does not apply
Reproductive Rates
Percentage adult females breeding: 100 with standard deviation (SD) due to environmental variation
of 10%. Eggs are visible through the thin semi-transparent skin at ventral side of the females body and I
observed the build-up of yolked oocytes over the spring and summer [15]. The first occurrence of mature
sized females without eggs coincided with the onset of egg-deposition, from which I conclude that
females skipping an annual breeding opportunity are absent or rare. Sequeira et al. observed that in
summer almost all adults had mature sperm (males) and oocytes (females) [20]. However, part of the
sample was drawn from the Lower mine, itself a breeding site, and may have been biased. Average
clutch size is 18 ± 1, as in [20].
Mortality Rates
Mortality at age 0, i.e. embryo and larval mortality (ql): The embryonic phase takes 12 weeks for
hatching [66,67]. Most larvae metamorphose at ca. 9 months [8,19] while some stay in the water for a
second year. In the modeling I equate the first year with the larval period. Under sensitivity testing larval
mortality is analyzed over the 0.0 to 1.0 range with increments of 0.01.
Mortality at age 1: It here concerns recently metamorphosed salamanders (“efts”) and a small
proportion of the cohort as second-year larvae [8]. Efts live in the spatter-zone and in the immediate
vicinity of the water courses [11].
Mortality at age 2: These are juveniles that generally live very close to the brook [11]. Mortality data
for these cohorts are unavailable. Considering the habitat selection over an increasingly wide zone along
the brook, annual mortality is scaled between larval mortality ql and adult mortality qb.
Mortality from age 4 onwards: qb = 0.22, qb = 0.28 (see above).
Mortality at age 3: These are young adults that are distinguished from full adults on the basis of body
size and the development of secondary sexual characteristics [8]. Mortality set as for the age 4 year class.
SD due to environmental variation is set at q/3.
Initial population size: 10,000
Carrying capacity: The genuine value for K is virtually impossible to be determined and I analyze the
effect over a large range (10,000–14,000–20,000–33,000–50,000–70,000–100,000).
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Catastrophes: none
Mate monopolization: none
Harvest: none
Supplementation: none
Genetics: not investigated
A3.2. Ribeira de Silveirinhos Population of Chioglossa lusitanica
As under 1, with the following changes:
Population demographic development at the Ribeira de Silveirinhos is expressed as the number of
adults in the breeding population (Nb), which is a proportion of the total population size N. The Nb/N
ratio is dependent on the larval mortality rate and was determined from the age distribution with Vortex
(Figure A3).
Number of years: 4, 12, 14, 30 and 32, corresponding to the adult population size estimates in 1984,
1992, 1994, 2010 and 2012.
Initial population size: N = 10,000 which roughly corresponds to Nb = 1324 + 2 × SE population
size in 1977.
Carrying capacity: K = 33,000 which refers to the Nb = 1974 + 2SE adult population size in 1994. K
was set at the high side in order not to force the model towards the observed population decline.
Figure A3. The contribution of adults to the total population of Chioglossa lusitanica
(vertical axis, N/Nb) as a function of larval mortality (horizontal axis, ql).
A3.3. Poço de Inferno Population of Chioglossa lusitanica
As under 1, with the following changes:
Number of years: 18, representing the 1977 to 1995 period in which the cumulative number of
observed embryos increased by an order of magnitude (Appendix 4).
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Initial population size: 10,000, representing the number of different adults observed in 1977
(Ńb = 1025, [15]).
Carrying capacity: K = 200,000, on the basis of population density relative to the Ribeira de Silveirinhos.
Appendix 4. Numerical Data on the Abundance of Chioglossa lusitanica in Two Study Areas of the
Serra de Santa Justa, Portugal over the 1976–2015 Period
Table A1. Dam Ribeira de Silveirinhos.
Year Adult Population Size ± Standard Error Method Source
1977 1324 ± 265 Weighted mean [8,15] 1984 2234 ± 488 Weighted mean [3] 1990 2117 Nil-recapture [4] 1992 1477 ± 207 Weighted mean [68] 1994 1974 ± 1352 Weighted mean [32] 2010 113 ± 56 Weighted mean 2012 10–50 Interpretation [34]
Table A2. Silveirihos brook.
Year Number of Larvae Observed in the Silveirinhos, Maximum (Date) *Number of Visits Source
First Year Cohort Second Year Cohort
1977 81 (3/7) 8 (20/4) 5 [8,15] 1994 46 (December) 40 (December) 1 [32] 1995 46 (June) 18 (March) 4 [32] 2014 1 (26/12) 2 (26/12) 1 2015 5 (15–16/4) 3 (15–16/4) 1
Table A3. Poço do Inferno mine galleries.
Year Largest Number of Adults Observed (Date)
Number of Visits Source Upper Mine Lower Mine
1977 78 (19/9) 100 (20/9) 22, 16 [8,15] 1978 63 (13/10) 116 (22/10) 4, 3 [8,15] 1981 100 (13/10) 175 (13/10) 6, 6 1984 56 (5/10) 134 (28/8) 6, 4 [3] 1992 37 (25/9) 141 (25/9) 1, 1 [68] 1994 117 (29/10) 153 (9/10) 6, 10 [51,66] 1995 209 (4/11) 199 (9/9) 25, 25 [51,66] 2007 311 (18/10) 216 (17/10) 1, 1 2010 284 (3/11) 227 (28/10) 3, 2 2012 146 (October) 121 (October) 1, 1 [34] 2013 264 (11/11) 253 (13/11) 2, 2 2014 279 (30/9) 336 (30/9) 1, 1
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Table A3. Cont.
Year Newly Deposited Eggs Totaled over Multiple Visits
Number of Visits Source Upper Mine Lower Mine
1977 334 208 22, 16 [15] 1995 2975 2050 25, 25 [51]
Year Maximum Number of Eggs and Embryos Observed
Number of Visits Source Upper Mine Lower Mine
1976 ** 487 169 1, 1 [15] 1978 130 78 4, 3 [8,15] 1981 219 233 6, 6 1984 97 922 6, 4 [3] 1988 56 987 Not reported [4] 1989 506 1200 Not reported [4] 1990 150 1562 Not reported [69] in [4] 1991 71 1778 2, 2 1991 213 2043 Not reported [4] 1992 46 2420 5, 5 [68] 1994 2536 1394 Not reported [32] 2010 2503 1369 3, 2 2012 2017 3283 3, 3 [34] 2013 970 720 2, 2 2014 1520 2039 1, 1
* over a 200 m long stretch of the brook. Data by V. Lima [32] were collected over 150 m; note that values in
Figure 2 are adjusted accordingly.
** the numbers refer to empty egg shells and molded eggs recorded in early spring 1977.
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Appendix 5
Figure A4. The probability of modeled population sizes of Chioglossa lusitanica at Ribeira
de Silveirinhos falling within the population size range estimated in the field(Ň ± SE), as a
function of larval mortality (ql, horizontal axis). Adult mortality qb = 0.28, otherwise as in
Figure 4. Support is maximal for ql = 0.65 (purple bar, p > 0.10). The grey rectangle indicates
the 0.61 < ql < 0.77 range over which none of the Ñ–Ň combinations are implausible (p > 0.05).
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